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Process for concentration of macromolecules

a macromolecule and solution technology, applied in the field of macromolecule solution concentration, can solve the problems of inability to achieve optimal protein concentration for products from solutions, limited, and conventional cell culture based protein manufacturing processes are the attainable concentration factors of protein isolation, so as to improve product yield, increase concentration factor, and reduce bulk protein precipitation

Active Publication Date: 2006-07-06
BAYER HEALTHCARE LLC
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Benefits of technology

[0013] In a particular embodiment, the present invention is directed to solving the problem of Pluronic-induced protein precipitation. In a first step, the cell culture supernatant is concentrated, preferably by ultrafiltration, to a concentration factor where product loss is minimal (for example 20 fold relative to the original concentration). Then, preferably using the same equipment, all or a portion of the concentrate obtained in the first step above is diafiltered against water (WFI) or another a suitable buffer to lower the conductivity to a point where Pluronic-induced product precipitation is substantially prevented, i.e. a conductivity of below 6 mS / cm, and more preferably from 0.5 to 5 mS / cm. As used herein, conductivity measurements are conducted at 22° C. unless described otherwise. Finally, the material is further concentrated to achieve high final concentration factors (e.g. 75-100× relative to the original concentration) with little or no product loss and with minimized bulk protein precipitation. All three steps can be performed in the same equipment. In this case, there is generally little or no increase in complexity and no new material or hardware qualification is necessary. The initial filtration step allows minimization of WFI or buffer consumption during the step of diafiltration. Because the additional volume that has to be filtered during the diafiltration step is therefore low (usually the additional volume required during diafiltration is less than 20%, often less then 15%), the overall process time is not significantly prolonged.
[0015] A process according to the present invention allows for a significant increase in concentration factor, i.e. from 20 fold to 100 fold and higher, while also improving product yield compared to a conventional process. The instant process provides process yields from 75% to 100%, preferably from 90%-100%, and in many cases, up to 95%, or even up to 99.5%, which, in prior art, can only be achieved for much lower concentration factors of less then 10 to 20 fold. Bulk protein precipitation is significantly reduced when a process according to the present invention is employed. For example, filterability for a 20 fold concentrate ranges from 6 to 10 ml (10 ml being the theoretical maximum) as measured using an Acrodisc syringe filter 25 ml manufactured by Pall Corporation having 2.8 square cm of filter area at 10 pounds of pressure. This is a significant improvement compared to 1 to 5 ml using prior art processes. Using a process according to the invention one achieves better filterability for 75 fold concentrate (6 ml on average) than for 20 fold concentrate using a conventional prior art process (approx. 3 ml on average; see, i.e., filterability data shown in FIG. 17).

Problems solved by technology

However, the ability to achieve optimal protein concentrations for products from solutions containing a co-concentrating organic polymer, such as is found in many cell culture supernatant solutions produced from mammalian cell culture harvest, has proved to be limited in the past due to increased precipitation (and thus loss) of the product molecules as concentration using ultrafiltration increases.
A major limitation of conventional cell culture based protein manufacturing processes is the attainable concentration factor of protein isolation.
Attempts to increase concentration have resulted in increasing filterability problems and product losses due to precipitation.
Significantly higher concentration in the UF step is typically not easily attainable due to further increased precipitation.
This can slow subsequent process steps because very large volumes have to be processed.

Method used

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  • Process for concentration of macromolecules
  • Process for concentration of macromolecules
  • Process for concentration of macromolecules

Examples

Experimental program
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Effect test

example 1

Identification of Nature of Precipitate

[0052] Analysis of the precipitate formed during ultrafiltration concentration of cell culture supernatant by infrared spectroscopy clearly identifies protein as the main component of the precipitate.

[0053] A 25 fold concentrated harvest from IL-2SA fermentation was obtained. The supernatant was subjected to centrifugation and the pellet re-dissolved in PBS. The UF concentrated harvest, supernatant of 25 fold concentration and redisolved pellet were analyzed by SDS gel electrophoresis followed by silver staining (see FIG. 3a) and immuno-staining (ZAP analysis) with an anti-hIL-2SA-antibody (see FIG. 3b). From FIG. 3a, (4) it can be seen that the precipitate, which was at least partially re-dissolved in buffer, indeed contains significant amounts of protein. As can be seen from FIG. 3b, (4) some IL-2SA also precipitates. However, the amount of precipitated IL-2SA seems to be relatively low (compare 3b, (4) and (3)), which is consistent with t...

example 2

Co-Concentration of Pluronic F-68

[0054] The average molecular weight of Pluronic F-68 is 8.4 kD, which is relatively large. Due to the formation of secondary membranes during ultrafiltration processes and the inherently inhomogeneous conditions along the crossflow channel, the selectivity of conventional UF technology does usually not allow significant separation of molecules in the size range of Pluronic. Even for 100 kD UF membranes, as used for the largest protein products like rFVIII or gp220 / 350, significant retention and co-concentration of polymers like Pluronic F-68 is usually found (see e.g. Schulz et al., 1997). It can be assumed that the retention coefficient R of Pluronic F-68 during the ultrafiltration process with, e.g., a 10 kD NMWCO (nominal molecular weight cut-off) will be close to 1 (or 100%). Since the Pluronic F-68 concentration in the medium required to obtain adequate cell protection during fermentation is 1 g / l (0.1%), 30 fold concentration would therefore ...

example 3

Spiking Experiments with Pluronic F-68

[0057] Since it has been demonstrated that the end concentration of Pluronic F-68 in ultrafiltration retentate is usually very high, spiking experiments with culture supernatant and concentrates of different concentration factors were performed in order to characterize the influence of these higher Pluronic F-68 concentrations on protein solubility. As can be seen from FIG. 5, spiking Pluronic F-68 into samples of pre-concentrated culture supernatant indeed causes strong precipitation. As expected, the Pluronic-F68 induced precipitation appears to be more severe for a higher concentration factor. FIG. 6 shows the remaining total protein in solution as measured by the Bradford assay (after centrifugation) as a function of concentration factor and Pluronic-F68 concentration. These results are consistent with the A580 measurements and confirm that the protein is precipitating out as a function of the added Pluronic F-68 concentration and the over...

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Abstract

The invention provides methods for concentrating a macromolecule from a solution comprising the macromolecule and an organic polymer by first subjecting the solution to ultrafiltration to produce a first retentate solution, then adjusting the conductivity of the first retentate solution such that any protein precipitation induced by the organic polymer is essentially prevented to produce a second retentate solution, and then subjecting the second retentate solution to ultrafiltration. In a preferred embodiment, the conductivity is adjusted by diafiltration against water, suitable diluent or buffer. Preferably, the invention pertains to the concentration of solutions of native or recombinant proteins. The invention further pertains preferably to methods for the concentration of cell culture supernatant comprising a product protein and organic polymers of the Pluronic family of block co-polymers, and more preferably comprising Pluronic F-68 block co-polymer.

Description

[0001] This claims priority to U.S. application Ser. No. 60 / 422,999, filed Nov. 1, 2002, which is hereby incorporated by reference herein in its entirety.BACKGROUND OF THE INVENTION [0002] 1. Field of the Invention [0003] The present invention relates generally to the concentration of solutions of macromolecules such as proteins. In one embodiment, the inventive process involves the ultrafiltration of a solution comprising macromolecules and co-concentrating organic polymer, then a diafiltration to reduce conductivity, and then a second ultrafiltration to concentrate the macromolecule without significant loss of yield due to precipitation. [0004] 2. Description of Related Art [0005] Protein production involves the creation of large volumes of comparatively dilute protein solution. It is preferred to concentrate the protein after fermentation to facilitate further steps, such as freezing, bulk storage and thawing and downstream purification. However, the ability to achieve optimal pr...

Claims

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Application Information

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Patent Type & Authority Applications(United States)
IPC IPC(8): C07K1/14A23J1/00C07K1/34C07K1/36C12N
CPCC07K1/34C07K1/36C07K14/55
Inventor KONSTANTINOV, KONSTANTINNGUYEN, HUONGVOGEL, JENS H.
Owner BAYER HEALTHCARE LLC
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